JP6449311B2 - Container house with reinforced insulation - Google Patents

Description

The present invention relates to a container house reinforced with heat insulation, and more particularly, to a container house reinforced with heat insulation that can realize a comfortable environment even in summer.

A container house is an assembly-type living space that allows people to live by routing electrical wiring inside a container and installing furniture for living. This type of container house insulates the inside of the container from the outside by assembling a heat insulating material on the side wall. At this time, assembling the heat insulating material, first, fix a number of reinforcing squares on the side wall using iron pieces or iron wires, cut and fit the insulating material such as foamed styrene between the squares, and then plaster This is done by fixing the board to the reinforcing square with nails. The related prior art of the container house is disclosed in Korean Utility Model Registration No. 20-0172590 under the title of wall laminated panel for container house.

However, in the case of the container house described above, since the heat insulating material is cut and fitted between the reinforcing squares, there is a gap between the reinforcing squares and the heat insulating material, and the insulation is good. could not.

In addition, in order to secure a space around which the electrical wiring for supplying electricity is routed, a groove was formed in the heat insulating material on the back side of the gypsum board, and the electrical wiring was fitted into the groove. . For this reason, when an electrical short circuit occurs and a spark occurs in the electrical wiring, there is a problem that a fire occurs while the foamed styrene insulation is burned.

Moreover, since the outer wall of the container house rose to 70 to 80 ° C. in summer, high heat was transferred to the electrical wiring as a result, and as a result, the insulating layer surrounding the electrical wiring was damaged or hardened. For this reason, there is a problem that the possibility of an electrical short increases with time.

Technical problems to be solved by the invention

The present invention has been devised in order to solve the above-described problems, and the first and second heat insulations are formed so that the first and second separation spaces made of an air layer are formed in the side wall portion and the ceiling portion. It is an object of the present invention to provide a container house reinforced with heat insulation that can provide a panel to maximize the heat insulation effect and thereby maintain a comfortable environment in summer and winter.

Another object of the present invention is that it is easy to assemble because it is not necessary to form a separate space for routing the electrical wiring, and even if a spark occurs due to an electrical short circuit, it is possible to eliminate the possibility of a fire. Is to provide a reinforced container house.

Yet another object of the present invention is that even if the side wall and the ceiling of the container house rise to 70 to 80 ° C. in midsummer, high heat is not transmitted to the electrical wiring, so the insulating layer surrounding the electrical wiring is damaged. It is an object of the present invention to provide a container house with a reinforced heat insulating property capable of preventing the hardening and the hardening from being promoted.

In order to achieve the above-described object, the container house reinforced with heat insulation according to the present invention includes a plurality of first separation members 20 welded to the side wall portion 13 inside the container body 10, and the container body 10. A number of second separation members 30 welded to the ceiling portion 14 on the inside and a number of first separation spaces D1 coupled to the first separation member 20 to form a first separation space D1 between the side wall portions 13. A plurality of heat insulation panels 40, a plurality of second heat insulation panels 50 coupled to the second separation member 30 to form a second separation space D2 between the ceiling portions 14, and the first and second insulation panels. And a large number of finishing panels 60 attached to the surfaces of the heat insulating panels 40, 50.

In the present invention, even if the first and second heat insulation panels 40 and 50 generate a spark in the electric wiring passing through the first and second separation spaces D1 and D2, a fire is generated by the spark. In order to prevent this, the sandwich panel is realized by attaching the second iron plates 42 and 52 to both surfaces of the first and second heat insulating materials 41 and 51 made of foamed styrene.

In the present invention, a first inflow vent hole 71 and a first exhaust vent hole 72 which are formed on one side and the other side of the container body 10 and communicate with the first separation space D1. And a fan unit 80 that communicates with the first discharge vent 72 and forms a negative pressure in the first separation spaces D1 and D2.

In the present invention, a second inflow vent hole 75 and a second exhaust vent hole 76 that are formed on one side and the other side of the container body 10 and communicate with the second separation space D2. And a fan unit 80 that communicates with the second discharge vent hole 76 to form a negative pressure in the second separation spaces D1 and D2.

In the present invention, the fan unit 80 is disposed in the fan housing 81 surrounding the first exhaust vent hole 72 or the second exhaust vent hole 76 and the fan housing 81, and the air inside the fan housing 81 is exhausted. A fan 82 for discharging to the outside is provided.

In the present invention, the first temperature sensor 91 that measures the temperature of the outside air and generates the corresponding first temperature signal S1, and measures the temperature of at least one of the side wall portion 13 and the ceiling portion 14 The second temperature sensor 92 for generating the second temperature signal S2 and the temperature difference measured by the first temperature signal S1 and the second temperature signal S2 is equal to or greater than a set temperature difference. A fan controller 90 having a fan operation unit 93 for operating the fan 80 is further provided.

In the present invention, the first separation space D1 is disposed in the first separation space D1, and a plurality of first vortices are formed so that air passing through the first separation space D1 flows while being in contact with the entire surface of the side wall portion 13. A vortex forming member 73 is further provided.

In the present invention, the second space D2 is disposed inside the second separation space D2, and a plurality of second vortexes are formed so that air passing therethrough flows while contacting the entire surface of the ceiling portion 14. A vortex forming member 77 is further provided.

In the present invention, the first inflow vent hole 71 or the second inflow vent hole 75 is surrounded so that rain and snow are not transferred, and is lower than the first inflow vent hole 71 or the second inflow vent hole 75. And a roof cover 100 having a structure in which a cover inlet 100a through which air flows is formed.

1 is a perspective view of a first embodiment of a container house reinforced with heat insulation according to the present invention. It is sectional drawing along the II-II line of FIG. It is a perspective view of 2nd Embodiment of the container house by which the heat insulation by this invention was reinforced. It is a figure for demonstrating that the 1st and 2nd inflow vent hole into which the air flows in into the container house of FIG. 3 and the 1st and 2nd exhaust vent to which air is discharged | emitted were formed. To explain that the air that has flowed into the first inflow vent hole in FIG. 4 passes through the first separation space between the side wall portion and the first heat insulation panel and then is discharged into the first exhaust vent hole. FIG. To explain that the air that has flowed into the second inflow vent hole in FIG. 4 passes through the second separation space between the ceiling portion and the second heat insulation panel and then is discharged into the second exhaust vent hole. FIG. In FIG. 3, it is a figure for demonstrating the roof cover for preventing rain and snow from flowing in into the 1st inflow ventilation hole and the 2nd inflow ventilation hole.

Hereinafter, the container house by this invention is demonstrated in detail based on an accompanying drawing.
FIG. 1 is a perspective view of a first embodiment of a container house reinforced with heat insulation according to the present invention, and FIG. 2 is a cross-sectional view taken along line II-II in FIG.

As shown in the figure, the container house according to the present invention is welded to the first separation member 20 welded to the side wall portion 13 inside the container body 10 and the ceiling portion 14 inside the container body 10. A plurality of second separation members 30, a plurality of first heat insulation panels 40 coupled to the first separation member 20 to form a first separation space D 1 between the side wall portions 13, and the first A plurality of second heat insulation panels 50 coupled to the two separation members 30 to form a second separation space D2 between the ceiling portions 14, and the surfaces of the first and second heat insulation panels 40, 50. And a number of finishing panels 60 to be affixed.

As shown in FIG. 1, the container body 10 includes a frame assembly 11 connected so as to form a hexahedron, a bottom surface portion 12 coupled to the frame assembly 11 to form a bottom surface, and a wall body surrounding the frame assembly 11. The side wall part 13 to be formed and the ceiling part 14 to form the ceiling of the frame assembly 11 are configured. At this time, the side wall 13 and the ceiling 14 are made of corrugated steel plates or flat steel plates in which valleys and peaks are formed. In this embodiment, the side walls 13 are made of corrugated steel plates, and the ceiling 14 is flat. The case where it consists of a shaped steel plate is illustrated. A door frame 15 and a window frame 16 are disposed on the side wall portion 13.

The first separation member 20 has a metal bar shape and is fixed to the side wall portion 13 by welding. Such a first separation member 20 fixes the first heat insulation panel 40 and forms a first separation space D1 between the side wall portion 13 and the first heat insulation panel 40.

The first separation space D <b> 1 formed by the first separation member 20 serves as a heat insulating layer, thereby blocking the heat outside the container body 10 from being transmitted to the first heat insulating panel 40. That is, an air layer is formed in the first separation space D1 and becomes a heat insulating layer independent of the first heat insulating panel 40. The first separation space D1 provides a space in which a number of electrical wirings (not shown) for supplying power to various electrical components disposed in the container body 10 are disposed.

The second separating member 30 has a metal bar shape and is fixed to the ceiling portion 14 by welding. Such a second separation member 30 fixes the second heat insulation panel 50 and forms a second separation space D2 between the ceiling portion 14 and the second heat insulation panel 50.

The second separation space D <b> 2 formed by the second separation member 30 serves as a heat insulating layer, thereby blocking the heat outside the container body 10 from being transmitted to the second heat insulating panel 50. That is, an air layer is formed in the second separation space D2 and becomes a heat insulating layer independent of the second heat insulating panel 50. The second separation space D2 provides a space in which a number of electrical wirings (not shown) for supplying power to various electrical components disposed in the container body 10 are disposed.

The first heat insulating panel 40 is a sandwich panel realized by attaching the first iron plate 42 to both surfaces of the first heat insulating material 41 such as foamed styrene. The first heat insulating panel 40 is separated from the side wall portion 13 by the first separating member 20. Fixed to leave. At this time, since the first heat insulating panel 40 has a structure in which the first iron plate 42 is attached to both surfaces of the first heat insulating material 41, the electrical wiring passing through the first separation space D1 is the first. The state of being separated from the heat insulating material 41 is maintained. For this reason, even if a short circuit occurs and a spark occurs in the electrical wiring, the spark is blocked by the first iron plate 42 and prevents the first heat insulating material 41 from being burned.

The second heat insulation panel 50 is a sandwich panel realized by attaching a second iron plate 52 to both surfaces of a second heat insulation material 51 such as foamed styrene, and is separated from the ceiling portion 14 by the second separation member 30. Fixed to leave. At this time, since the second heat insulating panel 50 has a structure in which the second iron plate 52 is attached to both surfaces of the second heat insulating material 51, the electrical wiring passing through the second separation space D2 is the second The state of being separated from the heat insulating material 51 is maintained. For this reason, even if a short circuit occurs and a spark occurs in the electrical wiring, the spark is blocked by the second iron plate 52 and prevents the second heat insulating material 51 from being burned.

The finishing panel 60 is affixed to the surfaces of the first and second heat insulating panels 40 and 50 for finishing, and is realized as a gypsum board or a veneer board. Wallpaper is applied to the finishing panel 60 or paint is applied to finish the inside of the container.

Thus, according to the container house, the first and second heat insulation panels 40 and 50 are disposed so as to be separated from the side wall portion 13 and the ceiling portion 14 by the first and second separation members 20 and 30. A first separation space D1 is formed between the side wall portion 13 and the first heat insulation panel 40, and a second separation space D2 is formed between the ceiling portion 14 and the second heat insulation panel 50. It is formed. For this reason, the first and second separated spaces D1 and D2 filled with air serve as the first heat insulation layer, and the first and second heat insulation panels 40 and 50 serve as the second heat insulation layer. The heat insulation layer can be formed to maximize the heat insulation effect, and heat outside the container body 10 can be effectively prevented from being transmitted to the inside.

In addition, the first and second separation spaces D1 and D2 are formed to provide a space in which a large number of electrical wirings for supplying power to the electrical components are routed. For this reason, it is not necessary to re-form the space through which the electrical wiring passes, so that the electrical wiring can be easily performed.

Further, since the first and second heat insulating panels 40 and 50 have a structure in which both surfaces of the first and second heat insulating materials 41 and 51 are bonded to the first and second iron plates 42 and 52, It is possible to prevent the electrical wiring passing through the first and second separation spaces D1 and D2 from being in direct contact with the first and second heat insulating materials 41 and 51. For this reason, even if a short circuit occurs and a spark occurs in the electrical wiring, the spark is blocked by the first and second iron plates 42 and 52, thereby the first and second heat insulating materials 41 and 51. Can be prevented from being burned by sparks, eliminating the possibility of fire.

In addition, by forming the first and second separation spaces D1 and D2 made of an air layer, soundproofing can be improved, thereby preventing external noise from flowing into the container house. be able to.

FIG. 3 is a perspective view of a second embodiment of a container house reinforced with heat insulation according to the present invention, and FIG. 4 is a first and second inflow vent hole through which air flows into the container house of FIG. It is a figure for demonstrating that the 1st and 2nd discharge ventilation hole from which air is discharged | emitted was formed. 5 shows that the air flowing into the first inflow vent of FIG. 4 is discharged to the first exhaust vent after passing through the first separation space between the side wall portion and the first heat insulation panel. FIG. 6 is a diagram for explaining that after the air flowing into the second inflow vent of FIG. 4 passes through the second separation space between the ceiling and the second heat insulation panel. It is a figure for demonstrating being discharged | emitted by the 2nd discharge ventilation hole. Further, FIG. 7 is a view for explaining a roof cover for preventing rain and snow from flowing into the first inflow vent hole and the second inflow vent hole in FIG. 3. Here, the same reference numerals as those in FIGS. 1 and 2 denote the same members having the same functions.

As shown in the figure, the second embodiment of the container house according to the present invention has been described in the first embodiment. In addition to the first and second separation members 20, 30, the first and second heat insulation panels 40, 50 and the finishing panel 60, the container body 10 is formed on one side and the other side. The first inflow vent hole 71 and the first exhaust vent hole 72 communicated with the first separation space D1, and formed on one side and the other side of the upper portion of the container body 10. The first inflow vent hole 75 and the second exhaust vent hole 76 communicated with the second separation space D2, and the first exhaust vent hole 72 and the second exhaust vent hole 76 communicated with the first exhaust vent hole 76. And the fan unit 80 that forms a negative pressure in the second separation spaces D1 and D2, and the temperature difference between the temperature of the outside air and at least one of the side wall portion 13 and the ceiling portion 14 is equal to or greater than the set temperature difference. Automatically activate fan unit 80 in some cases Comprises a § emission controller 90, a roof cover 100 for rain or snow is prevented from entering the first inlet vent 71 and the second inlet vents 75, a.

As shown in FIG. 5, the first inflow vent hole 71 and the second exhaust vent hole 72 communicate with the first separation space D <b> 1, and are formed on one side and the other side of the side wall portion 13. A passage is formed through which air flows in and out.

As shown in FIG. 6, the second inflow vent hole 75 and the second exhaust vent hole 76 communicate with the second separation space D <b> 2, and are provided on one side and the other side of the ceiling portion 14. A passage is formed through which air flows in and out.

In the present embodiment, for ease of explanation, the first separation space D1 and the second separation space D2 have been described as independent components, but the first and second separation spaces D1, D2 communicate with each other. Needless to say, it may be allowed.

The fan unit 80 communicates with the first exhaust vent hole 72 and / or the second exhaust vent hole 76 to form negative pressure in the first and second separation spaces D1 and D2, and thereby The outside air is caused to flow into the two inflow vent holes 71 and 75. For this purpose, as shown in FIGS. 4 to 6, the fan unit 80 is disposed in the fan housing 81 surrounding the first and second exhaust vent holes 72, 76, and the fan housing 81. And a fan 82 for discharging the air inside the outside.

In the present embodiment, the fan unit 80 is described as a single component that communicates with the first and second exhaust vent holes 72 and 76 simultaneously. However, it goes without saying that the fan unit may be realized as an independent component communicated with each of the first exhaust vent hole 72 and the second exhaust vent hole 76. That is, the fan unit 80 includes a fan housing 81 that surrounds the first exhaust vent 72 and a fan 82 that is disposed in the fan housing 81 and exhausts air inside the fan housing 81 to the outside. Also good. Alternatively, the fan unit 80 includes a fan housing 81 that surrounds the second exhaust vent 76 and a fan 82 that is disposed in the fan housing 81 and exhausts the air inside the fan housing 81 to the outside. Also good.

Since the first separation space D1 is formed between the side wall portion 13 and the first heat insulation panel 40, when the fan unit 80 is operated, the external air is first refrigerated as shown in FIG. The air is discharged through the inflow vent 71, the first separation space D1, and the first discharge vent 72. In this process, the outside air absorbs the heat of the side wall 13 and the first heat insulation panel 40. Therefore, even if the temperature of the side wall 13 rises to 70 to 80 ° C. or higher, the high heat is the first. Transmission to the heat insulation panel 40 can be suppressed as much as possible.

At this time, as shown in FIG. 6, a large number of first vortex forming members 73 are staggered in the first separation space D <b> 1 so that the air passing through the first separation space D <b> 1 flows while contacting the entire surface of the side wall portion 13. Arranged in a shape. For this reason, as shown in FIG. 5, the air flowing through the first separation space D1 after flowing into the first inflow vent hole 71 collides with a large number of first vortex forming members 73 to form vortex flows while forming side walls. The air flows while being in contact with the entire surface of the portion 13, and therefore, the air is more effectively absorbed into the side wall portion 13 and exhausted, so that the air is transmitted to the first heat insulating panel 40 through the side wall portion 13. Heat conduction can be suppressed as much as possible.

Since the second separation space D2 is formed between the ceiling portion 14 and the second heat insulation panel 50, when the fan unit 80 is operated, the external air is second as shown in FIG. The air is discharged via the inflow vent hole 75, the second separation space D2, and the second exhaust vent hole 76. In this process, since the outside air absorbs the heat of the ceiling part 14 and the second heat insulation panel 50, even if the temperature of the ceiling part 14 rises to 70 to 80 ° C. or higher, the high heat is the second. It is possible to suppress transmission to the heat insulation panel 50 as much as possible.

At this time, as shown in FIG. 4, a large number of second eddy current forming members 77 are staggered in the second separation space D <b> 2 so that air passing through the second separation space D <b> 2 is in contact with the entire surface of the ceiling portion 14. Arranged in a shape. For this reason, as shown in FIG. 6, the air flowing through the second separation space D2 after flowing into the second inflow vent hole 75 collides with a number of second eddy current forming members 77 to form a vortex, thereby forming a ceiling. The air flows while being in contact with the entire surface of the portion 14. For this reason, the air is more effectively absorbed and exhausted by the heat transmitted to the ceiling portion 14, so that the air is discharged to the second heat insulation panel 50 through the ceiling portion 14. Conducted heat conduction can be minimized.

The fan controller 90 measures the temperature of at least one of the first temperature sensor 91 that measures the temperature of the outside air and generates a corresponding first temperature signal S1, and the side wall portion 13 and the ceiling portion 14. The second temperature sensor 92 for generating the corresponding second temperature signal S2 and the temperature difference measured by the first temperature signal S1 and the second temperature signal S2 is equal to or greater than the set temperature difference. A fan actuating part 93 that actuates the fan unit 80.

For example, when the temperature of the outside air reaches 30 ° C., the temperature of the ceiling part 14 of the container body rises to 70 to 80 ° C. or more, and therefore the temperature inside the first and second separation spaces D1 and D2 is also 70 to 80. It rises rapidly to ℃. In this case, high heat is transmitted to the first and second heat insulating panels 40 and 50, and the temperature inside the container house rapidly increases.

However, by adopting the fan controller 90, the temperature difference between the temperature of the outside air measured by the first temperature sensor 91 and the side wall part 13 or the ceiling part 14 measured by the second temperature sensor 92 is increased. When a difference equal to or higher than a set temperature, for example, a set temperature of 10 ° C., the fan operating unit 93 operates the fan 82 of the fan unit. Then, external air flows into the first and second inflow vent holes 7175 while negative pressure is formed in the first and second exhaust vent holes 72 and 76, and such air is supplied to the first and second exhaust vent holes 7175. After passing through the separated spaces D1 and D2, the air is exhausted to the outside through the first and second exhaust vent holes 72 and 76 and the fan 80. At this time, the outside air absorbs the temperature of the side wall portion 13 and the ceiling portion 14 and discharges the heated air in the first and second separation spaces D1 and D2, whereby the first and second heat insulation panels are discharged. The heat applied to 40 and 50 can be suppressed as much as possible. As a result, the heat insulation effect can be maximized and the temperature inside the container house can be prevented from rapidly rising.

As shown in FIG. 7, the roof cover 100 is disposed in a predetermined portion of the container body 10 to prevent rain and snow from flowing into the first inflow vent hole 71 and the second inflow vent hole 72. Such a roof cover 100 surrounds the first inflow vent hole 71 and / or the second inflow vent hole 75 so that rain or snow does not fall, and is more than the first and second inflow vent holes 71, 75. A cover inlet 100a through which air flows is formed on the lower side. Thus, rain and snow are prevented from flowing into the first and second inflow vent holes 71 and 75 by the roof cover 100, but the air passes through the cover inlet 100a and the first and second inflow vent holes 71, 75 flows into.

As described above, according to the second embodiment of the container house with enhanced heat insulation according to the present invention, when the temperature of the outside air rises and the side wall portion 13 and the ceiling portion 14 are overheated, the fan controller 90 is By operating 80, air is forced to flow in through the first and second inflow vent holes 71, 75, and the forced air flows in the first and second separation spaces D1, D2. After passing, the air is discharged to the first and second discharge vent holes 72 and 76. In this process, the air passing through the first and second separation spaces D1 and D2 collides with the first and second vortex forming members 73 and 77 to form vortex flows, and forms the side wall portion 13 and the ceiling portion 14. After effectively absorbing the heat transmitted to the side wall portion 13 and the ceiling portion 14 while being in contact with the entire surface, the air is exhausted. For this reason, conduction of the heat transmitted to the first and second heat insulating panels 40 and 50 through the side wall portion 13 and the ceiling portion 14 can be suppressed as much as possible.

In addition, since the temperature inside the first and second separation spaces D1 and D2 decreases, the insulating layer of the electrical wiring disposed in the first and second separation spaces D1 and D2 is damaged by high heat. It can be prevented from curing quickly.

Although the present invention has been described based on one illustrated embodiment, this is merely an example, and various modifications and other equivalent implementations will occur to those skilled in the art. It should be understood that the form is feasible.

According to the present invention, the first and second heat insulation panels 40 and 50 are provided so that the first and second separation spaces D1 and D2 made of an air layer are formed in the side wall portion 13 and the ceiling portion 14 to provide heat insulation. The effect can be maximized, and a comfortable environment can be maintained in summer and winter. In particular, when the temperature of the outside air rises and the side wall portion 13 and the ceiling portion 14 are overheated, the fan controller 90 automatically operates the fan 80. Therefore, after the heat of the side wall portion 13 and the ceiling portion 14 is absorbed. Can be exhausted. Thereby, conduction of heat transmitted to the first and second heat insulating panels 40 and 50 via the side wall portion 13 and the ceiling portion 14 can be suppressed as much as possible, and the heat insulating effect can be further maximized.

In addition, by forming the first and second separation spaces D1 and D2, it is not necessary to form a separate space for routing a large number of electrical wires, so that assembly is easy, even if an electric short circuit causes a spark. Even the possibility of fire can be eliminated.

Furthermore, even if the side wall and ceiling of the container house rise to 70-80 ° C. in midsummer, high heat will not be transmitted to the electric wiring, so the insulating layer surrounding the electric wiring will be damaged or hardened. Can be prevented.

Furthermore, the sound insulation can be improved by forming the first and second separated spaces D1 and D2 made of an air layer, thereby preventing external noise from flowing into the container house. be able to.

Claims (9)

A number of first spacing members (20) welded to the side wall (13) inside the container body (10);
A number of second spacing members (30) welded to the ceiling (14) inside the container body (10);
A plurality of first heat insulation panels (40) coupled to the first separation member (20) to form a first separation space (D1) between the side wall portions (13);
A plurality of second heat insulation panels (50) coupled to the second separation member (30) to form a second separation space (D2) between the ceiling portions (14);
A number of finishing panels (60) affixed to the surfaces of the first and second thermal insulation panels (40), (50);
A container house reinforced with heat insulation. The first and second heat insulation panels (40), (50) are:
In order to prevent the occurrence of a fire due to the spark even if a spark occurs in the electrical wiring passing through the first and second separated spaces (D1) and (D2), The heat insulating property according to claim 1, wherein the heat insulating material is a sandwich panel realized by attaching the second iron plates (42), (52) to both surfaces of the heat insulating materials (41), (51). Container house. A first inflow vent hole (71) and a first exhaust passage formed on one side and the other side of the container body (10) and communicating with the first separation space (D1). Pores (72);
A fan unit (80) communicating with the first discharge vent (72) to form a negative pressure in the first separation spaces (D1), (D2);
The container house reinforced with heat insulation according to claim 1, further comprising: A second inflow vent hole (75) and a second discharge passage formed on one side and the other side of the container body (10) and communicating with the second separation space (D2). Pores (76);
A fan unit (80) communicating with the second discharge vent (76) to form a negative pressure in the second separation spaces (D1), (D2);
The container house reinforced with heat insulation according to claim 1, further comprising: The fan unit (80)
A fan housing (81) surrounding the first exhaust vent (72) or the second exhaust vent (76), and the fan housing (81) are arranged in the fan housing (81) to allow air inside the fan housing (81) to flow. The container house reinforced with heat insulation according to claim 3 or 4, further comprising a fan (82) for discharging to the outside. The first temperature sensor (91) that measures the temperature of the outside air and generates a corresponding first temperature signal (S1), and the temperature of at least one of the side wall (13) and the ceiling (14). A second temperature sensor (92) that measures and generates a corresponding second temperature signal (S2), and a temperature difference measured by the first temperature signal (S1) and the second temperature signal (S2) The fan controller (90) further comprising a fan operating unit (93) that operates the fan (80) when the temperature difference is equal to or greater than a set temperature difference. Container house with reinforced thermal insulation. A plurality of first vortexes are arranged in the first separation space (D1), and form vortices so that air passing through the first separation space (D1) flows while being in contact with the entire surface of the side wall (13). The container house reinforced with heat insulation according to claim 3, further comprising a swirl forming member (73). A plurality of second spaces which are arranged inside the second separation space (D2) and form vortexes so that air passing therethrough flows while contacting the entire surface of the ceiling (14). The container house reinforced with heat insulation according to claim 4, further comprising a vortex forming member (77). The first inflow vent hole (71) or the second inflow vent hole (75) is surrounded by rain or snow so as not to be transferred, and the first inflow vent hole (71) or the second inflow vent hole (75). The heat insulating property according to claim 3 or 4, further comprising a roof cover (100) having a structure in which a cover inlet (100a) through which air flows is formed on the lower side. Container house.